I.4 Modified secondary protection _______________ INTERNATIONAL TELECOMMUNICATION UNION CCITT K.20 THE INTERNATIONAL TELEGRAPH AND TELEPHONE CONSULTATIVE COMMITTEE PROTECTION AGAINST INTERFERENCE RESISTIBILITY OF TELECOMMUNICATION SWITCHING EQUIPMENT TO OVERVOLTAGES AND OVERCURRENTS Recommendation K.20 Geneva, 1991 Printed in Switzerland FOREWORD The CCITT (the International Telegraph and Telephone Consultative Committee) is a permanent organ of the International Telecommunication Union (ITU). CCITT is responsible for studying technical, operating and tariff questions and issuing Recommendations on them with a view to standardizing telecommunications on a worldwide basis. The Plenary Assembly of CCITT which meets every four years, establishes the topics for study and approves Recommendations prepared by its Study Groups. The approval of Recommenda- tions by the members of CCITT between Plenary Assemblies is covered by the procedure laid down in CCITT Resolution No. 2 (Melbourne, 1988). Recommendation K.20 was prepared by Study Group V and was approved under the Resolution No. 2 procedure on the 18th of March 1991. ___________________ CCITT NOTE In this Recommendation, the expression "Administration" is used for conciseness to indicate both a telecom- munication Administration and a recognized private operating agency. aITU1991 All rights reserved. No part of this publication may be reproduced or utilized in any form or by any means, elec- tronic or mechanical, including photocopying and microfilm, without permission in writing from the ITU. PAGE BLANCHE Recommendation K.20 Recommendation K.20 RESISTIBILITY OF TELECOMMUNICATION SWITCHING EQUIPMENT TO OVERVOLTAGES AND OVERCURRENTS (Malaga-Torremolinos, 1984; revised in 1990) 1 General This Recommendation seeks to establish fundamental testing methods and criteria for the resistibility of telecommunication switching equipment to overvoltages and overcurrents. It should be read in conjunction with the CCITT Manual, Protection of telecommunication lines and equipment against lightning discharges and Recommendation K.11 which deals with the general eco- nomic and technical aspects of protection. The methods may be varied in the light of particular local circumstances and technical developments. 2 Scope The Recommendation relates to telephone exchanges and similar telecommunication switching centres and is concerned mainly with test conditions to be applied to points intended for the connec- tion of 2-wire subscriber lines. Ports carrying more complex circuits or more concentrated traffic (such as junctions or multi-channel circuits) may be tested either in accordance with this Recom- mendation or in accordance with other Recommendations such as K.15 and K.17, as considered appro- priate. The tests are type tests and, although they are applicable to a complete switching centre, it is recognized that they may be applied to individual items of equipment during development and design work. In making the tests, it is necessary to take account of any switching conditions, either in the unit under test or elsewhere, which may affect the results. 3 Overvoltages and overcurrent conditions Aspects of overvoltage or overcurrent covered by this Recommendation are: – surges due to lightning strokes on or near to the line plant; (equipment complying with this Rec- ommendation may not necessarily resist severe direct lightning strokes); – short-term induction of alternating voltages from adjacent power lines or railway systems, usually when these lines or systems develop faults; – direct contacts between telecommunication lines and power lines, usually of a low voltage nature. It is recognized that under some circumstances. problems may arise if overvoltages or overcurrents occur simultaneously on a number of lines and produce large currents in common wiring or components. Such conditions are not covered by this Recommendation at this time and the subject is still being studied in CCITT (see AppendixI -Information about practical experiences in Norway). The aspects of rise of earth potential are not covered but are being studied in CCITT. 4 Levels of resistibility 4.1 Only two levels of resistibility are covered: a lower level suitable for unexposed environ- ments where overvoltages and overcurrents are low, and a higher level for more exposed environ- ments. Account is taken of the fact that in the more exposed environments, protection may be fitted on the main distribution frame (MDF) or elsewhere outside the equipment. 4.2 Extreme conditions are not covered. In very sheltered environments, it may be possible for equipment of lower resistibility than specified herein to operate satisfactorily. On the other hand, equipment with even higher resistibility than specified may be needed for exceptionally exposed environments. Equally, other combinations of equipment resistibility and external protection are possible. For example, certain equipment may require protection even in unexposed environments and other equipment may operate satisfactorily in exposed environments without external protection. Although only two categories of resistibility are described in this Recommendation, these cover a large proportion of present-day needs. 4.3 It is for Administrations to classify the environment of a particular switching centre, taking into account business policy, economic and technical considerations. Recommendation K.11 gives information to help in making this decision. 4.4 The test conditions and voltages of Table 1/K.20 reflect the conditions which are expected to occur on lines in unexposed environments. 4.5 The test conditions and voltages of Table 2/K.20 simulate the effects of an exposed envi- ronment on equipment protected by main distribution frame protectors and constitute additional requirements to ensure compatibility with external protection and proper functioning in the more severe environment. Higher voltages may well occur on the lines, but because the MDF protection operates, the effects on the equipment may not be more severe. 4.6 Equipment satisfying the requirements for an exposed environment may be used in either envi- ronment, but equipment satisfying only the requirements for an unexposed environment should be used only in an unexposed environment. 5 Exchange equipment boundary The variations of different types of equipment make it necessary for each exchange to be seen as a "black-box" having three terminals, A, B and Earth. It is likely that some protective devices have already been provided in the equipment, either distributed on its line-cards, etc., or connected to its terminals. For the purpose of these tests, manufacturers are expected to define the bound- aries of the "black-box" and any protective device which is included must be considered an immu- table part of that exchange. 6 Test conditions The following conditions apply to all the tests specified in _ 8. 6.1 All tests are type tests. 6.2 The input terminals at which tests on the equipment are to be applied should be identified by the manufacturer and labelled A, B and Earth. 6.3 The equipment should be tested in any operating state of significant duration. 6.4 The equipment should be able to pass the tests in _ 8 throughout the ranges of temperature and humidity of its intended use. 6.5 For tests in the "exposed" situation, it is current practice to protect subscribers' lines at the MDF with some surge protectors such as gas-discharge tubes. Recognizing that such a device is likely to be needed in most cases to handle high surge currents, and that the operation of these protectors exposes exchange switching equipment to other modified conditions, the characteristics of the external protectors to be used should be agreed between the equipment supplier and the Admin- istration. Protectors having characteristics within the agreed range should be used where speci- fied in Table 2/K.20. A new set of protectors may be used after the completion of each test sequence. Alternatively, some Administrations may choose to omit the external protectors but to modify the applied voltages and durations so that the conditions applied to the equipment are the same as could reasonably be expected to occur under the conditions of Table 2/K.20. 6.6 In all cases where a maximum voltage is specified, tests should also be made at lower voltages if this is necessary to confirm that the equipment will resist any voltage up to the maxi- mum value specified. 6.7 Each test should be applied the number of times indicated in the relevant table. The time interval between applications should be 1 minute and, in the case of pulse tests, the polarity should be reversed between consecutive pulses. 6.8 Power induction and power contact tests should be made at the frequencies of the a.c. mains or electric railways used in the country of application. 7 Permitted malfunction or damage Two levels of malfunction or damage are recognized: Criterion A – Equipment shall withstand the test without damage or other disturbance (such as corruption of software or misoperation of fault-protection facilities) and shall oper- ate properly within the specified limits after the test. (It is not required to operate correctly while the test condition is present.) If specifically permitted by the Administration, the test may cause the operation of fuses or other devices which have to be replaced or reset before normal operation is restored. Criterion B – A fire hazard should not arise in the equipment as a result of the tests. Any damage or permanent malfunction occurring should be confined to a small number of external line interface circuits. The conditions likely to give rise to criterion B are considered to be so rare that complete protection against them is not economical. 8 Tests 8.1 General The test circuits used for the three overvoltage or overcurrent situations are as follows: – Figure 1/K.20: lightning surges; – Figure 2/K.20: power induction; – Figure 3/K.20: power contacts. Note – Certain considerations which justify the test proposals are stated in Annex A. The response of equipment to lightning surges may be modified by the input impedance of the equipment. To explain this effect, Annex A includes an example in which, for clarity, values are assigned to the input impedance so that instantaneous levels of voltage at different points in the circuit may be compared. These values are included for illustration only and do not form any part of this Recom- mendation. 8.2 Unexposed environment Equipment for use without external protection in unexposed environments should be tested according to Table 1/K.20. 8.3 Exposed environment Equipment for use in exposed environments should pass the tests described in Table 1/K.20 and also those in Table 2/K.20. Figure 1/K.20 = 11cm = 430 Figure 2/K.20 = 6.5 cm = 250 Figure 3/K.20 = 5.5 cm = 215 ANNEX A (to Recommendation K.20) Explanations which illustrate test conditions A.1 Lightning surges A.1.1 Operation of simulation circuit Figure A-1/K.20 shows the test generator of Figure 1/K.20 connected to an example of an exchange circuit with primary protection provided at the MDF and secondary protection in the exchange equipment itself. Apart from the test generator of Figure 1/K.20, all the circuit layout and compo- nent values have been chosen purely for explanatory purposes and are not put forward as some recommended practice. When the charging voltage, Uc, is progressively raised, the voltages and currents which occur at various points in the circuit of Figure A-1/K.20 are shown on the graph in Figure A-2/K.20. For Uc = 0-300 V, the current flows only through the 100 W resistor in the equipment. At Uc = 300 V, the secondary protection operates and the current IT rises more rapidly. At Uc = 2385 V, the voltage U across the primary protection reaches Us = 700 V in the case illustrated, and IE reaches its maximum value of 3 A. The primary protection operates when Uc = 2385 V and the total current thereafter rises still more rapidly, reaching 100 A when Uc = 4 kV. The voltage U however drops to a low value and the current IE flowing into the equipment falls to a very low value and becomes practically independent of Uc. Figure A-1/K.20 = 5cm = 195 Figure A-2/K.20 = 17.5 = 684 A.1.2 Effect of protective devices Operation of the primary protection when U = Us therefore has two effects: – It limits the maximum voltage applied to the equipment and hence, depending on the internal imped- ance of the equipment, the maximum current which the equipment must withstand. – It produces a very rapid change in U and I which, by inductive or capacitive effects can reach sensi- tive parts of the exchange switching equipment not apparently exposed to line voltages. For these reasons it is important that the Administration and equipment suppliers should agree on the primary protection which should be used and for the equipment user to provide or simu- late this protection when tests are made. The tolerances allowed for such protection components should be taken into account when tests are made. A.2 Power induction Induced voltages are likely to occur more on long lines, and in the general case where subscrib- ers' lines do not provide a low resistance earth, induced voltages may be considered to have a high source impedance consisting of a 600 W wire resistance in series with 1 mF line to earth capacitance as shown in Figure A-3/K.20. Tests 3(a) and 3(b) of Table 2/K.20 represent typical requirements for long and short lines respectively but they do not necessarily provide for limiting conditions. The gas discharge tube shown in Figure A- 3/K.20 only exists on exposed lines. Such tubes are represented by S2 in Figure 2/K.20 and the telephone is repre- sented by S1. CCITT Directives admit induced voltages up to 430 V from normal power lines and 650 V from high-secu- rity lines, but most Administrations expect voltages to be below 300 V except on the lines in exposed environments. Figure A-3/K.20 = 7cm = 273 A.3 Power contacts Direct contact with electrical mains power can occur through network line or cable faults, faulty or unapproved subscriber equipment or other causes. The contact may not cause the opera- tion of a power system circuit-breaker. A.c. currents resulting from a direct contact may make effective protection both difficult and expensive. As such events are rare, equipment is not required to withstand overvoltages or overcurrents arising from direct contacts but may fail in an acceptable manner. Two particular dangers to equipment may arise: – A contact near to an exchange where the combined impedance of the cable circuit and exchange termi- nation is low and a high current flow occurs. This condition is simulated by the test in FigureA-4/K.20 by applying 220 V through an impedance of 10 W. – A contact at the maximum distance from an exchange where the combined impedance of the cable cir- cuit and exchange termination is high and a small but harmful current flows continuously. This condition is simu- lated by the test in Figure A-4/K.20 by applying 220 V through an impedance of 600W. Figure A-4/K.20 = 6.5cm = 254 APPENDIX I Over-voltages occurring simultaneously on a number of telephone lines (Information about practical experience in Norway) I.1 Type test The overvoltage resistibility of a new digital exchange system introduced in Norway was tested according to the requirements specified in this Recommendation. The acceptance test was performed on a 2-wire basis on a complete installation with the prescribed 1kV and 4kV pulse voltages. The equipment under test complied with the specified test requirements. I.2 Effects of lightning Practical experience with this particular exchange system showed that a large number of line cards in the exchanges were damaged by lightning. The damage mainly appeared in rural areas defined as exposed environments. In such areas in Norway, all telephone lines entering electronic exchanges are protected with gas discharge tubes at the MDF. I.3 Lightning simulation A complete overvoltage test according to this Recommendation was performed on site on one of the installation where line cards had earlier been damaged by lightning. Again the system complied with the test requirements, and no weakness was revealed in the system. Overvoltages were then imposed simultaneously on a number of lines as shown in Figure I- 1/K.20. Figure I-1/K.20 = 10 cm = 395 The circuit shown was used to impose negative pulses. To apply positive pulses the diodes were connected in the opposite direction. The experiment revealed that the exchange responded differently to positive and negative surges. No damage appeared from the positive surges, but when negative surges were imposed on more than 20 line inputs simultaneously, the line cards showed the same type of damage as discovered after lightning storms. Abstracts taken from the test report show (see Table I-1/K.20): Originally the secondary protection on the line cards drained positive current pulses to the chassis, and negative pulses to the -48Vd.c. power supply. The secondary protection was modified by the manufacturer so that both positive and negative pulses were later drained to the chassis. After having all the line cards in a small exchange modified, the complete installation was tested on site with positive and negative surges imposed simultaneously on 1 to 40 line inputs with the circuit shown in FigureI-1/ K.20. No failures in the exchange were detected during this test. The modified exchange serves customers connected via exposed lines. After the modification, the exchange has given satisfactory service during thunderstorms. Based on the on-site test experiment and the results from the field trial, it was decided to have new line cards for this particular exchange system produced with the mentioned modification. I.5 Conclusion When testing the resistibility of switching equipment to overvoltages and overcurrents, the user should be aware of the possibility that the exchange may respond differently to positive and negative surges. Furthermore, the EUT may respond differently to surges imposed on a single pair (as shown in Figure1/K.20) and surges imposed on a group of lines.